Ciphey | ⚡ Automatically decrypt encryptions without knowing the key | Cryptography library

 by   Ciphey Python Version: 5.14.0 License: MIT

kandi X-RAY | Ciphey Summary

kandi X-RAY | Ciphey Summary

Ciphey is a Python library typically used in Institutions, Learning, Education, Security, Cryptography applications. Ciphey has no bugs, it has no vulnerabilities, it has a Permissive License and it has medium support. However Ciphey build file is not available. You can install using 'pip install Ciphey' or download it from GitHub, PyPI.

Input encrypted text, get the decrypted text back. "What type of encryption?". That's the point. You don't know, you just know it's possibly encrypted. Ciphey will figure it out for you. Ciphey can solve most things in 3 seconds or less. Ciphey aims to be a tool to automate a lot of decryptions & decodings such as multiple base encodings, classical ciphers, hashes or more advanced cryptography. If you don't know much about cryptography, or you want to quickly check the ciphertext before working on it yourself, Ciphey is for you. The technical part. Ciphey uses a custom built artificial intelligence module (AuSearch) with a Cipher Detection Interface to approximate what something is encrypted with. And then a custom-built, customisable natural language processing Language Checker Interface, which can detect when the given text becomes plaintext. No neural networks or bloated AI here. We only use what is fast and minimal. And that's just the tip of the iceberg. For the full technical explanation, check out our documentation.
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            kandi-support Support

              Ciphey has a medium active ecosystem.
              It has 13505 star(s) with 828 fork(s). There are 219 watchers for this library.
              OutlinedDot
              It had no major release in the last 12 months.
              There are 45 open issues and 259 have been closed. On average issues are closed in 70 days. There are 10 open pull requests and 0 closed requests.
              It has a neutral sentiment in the developer community.
              The latest version of Ciphey is 5.14.0

            kandi-Quality Quality

              Ciphey has 0 bugs and 0 code smells.

            kandi-Security Security

              Ciphey has no vulnerabilities reported, and its dependent libraries have no vulnerabilities reported.
              Ciphey code analysis shows 0 unresolved vulnerabilities.
              There are 0 security hotspots that need review.

            kandi-License License

              Ciphey is licensed under the MIT License. This license is Permissive.
              Permissive licenses have the least restrictions, and you can use them in most projects.

            kandi-Reuse Reuse

              Ciphey releases are available to install and integrate.
              Deployable package is available in PyPI.
              Ciphey has no build file. You will be need to create the build yourself to build the component from source.
              Installation instructions are available. Examples and code snippets are not available.
              Ciphey saves you 2088 person hours of effort in developing the same functionality from scratch.
              It has 4689 lines of code, 530 functions and 87 files.
              It has medium code complexity. Code complexity directly impacts maintainability of the code.

            Top functions reviewed by kandi - BETA

            kandi has reviewed Ciphey and discovered the below as its top functions. This is intended to give you an instant insight into Ciphey implemented functionality, and help decide if they suit your requirements.
            • Complete the configuration
            • Load checker objects
            • Load modules
            • Set the logging level
            • Create a new class
            • Create a lambda function
            • Dispatches the given function to the given function
            • Update a named parameter
            • Return the named name
            • Performs a star algorithm from start_node to stop_node
            • Return the neighbors of v
            • Load configuration from a file
            • Merge values from a config file
            • Check all required parameters
            • Get parameters
            • Sort prob_table according to prob_table
            • Sort a dictionary based on a key
            • Print help menu
            • Run coverage
            • Threads through ctext
            • Decrypt the contents of the ctext
            • Load a resource from the registry
            • Run the checker
            • Set verbosity
            • Perform aStar algorithm
            • Install Sphinx docs
            Get all kandi verified functions for this library.

            Ciphey Key Features

            No Key Features are available at this moment for Ciphey.

            Ciphey Examples and Code Snippets

            Currently supported encryption methods,How to delete ciphers you don't like
            Pythondot img1Lines of Code : 10dot img1License : Permissive (MIT)
            copy iconCopy
            self.methods = [
                self.Base64,
                self.Ascii,
                self.Base16,
                self.Base32,
                self.Binary,
                self.Hex,
                self.MorseCode,
                self.Reverse,
            ]
              
            How to use
            Pythondot img2Lines of Code : 4dot img2License : Permissive (MIT)
            copy iconCopy
            >>> import encipher_crypto
            >>> obj = encipher_crypto.encipher_crypto
            >>> print(obj.randomEncrypt("Text you want to encrypt here")
            
            {"PlainText": text, "EncryptedText": encryptedText, "CipherUsed": name}
              

            Community Discussions

            QUESTION

            ECSDA sign with Python, verify with JS
            Asked 2022-Apr-10 at 18:16

            I'm trying to achieve the exact opposite of this here where I need to sign a payload in Python using ECDSA and be able to verify the signature in JS.

            Here is my attempt, but I'm pretty sure I'm missing something with data transformation on either or both ends.

            (Key types are the same as in the answer provided to the question above)

            I've tried some other variations but nothing worked so far.

            (The verification on JS returns False)

            Python:

            ...

            ANSWER

            Answered 2022-Apr-10 at 18:16

            The main problem is that both codes use different signature formats:
            sign_payload() in the Python code generates an ECDSA signature in ASN.1/DER format. The WebCrypto API on the other hand can only handle the IEEE P1363 format.
            Since the Python Cryptography library is much more convenient than the low level WebCrypto API it makes sense to do the conversion in Python code.

            The following Python code is based on your code, but additionally performs the transformation into the IEEE P1363 format at the end:

            Source https://stackoverflow.com/questions/71818496

            QUESTION

            How to calculate sha 512 hash properly in .NET 6
            Asked 2022-Mar-30 at 04:56

            In .NET 6 code from How can I SHA512 a string in C#?

            ...

            ANSWER

            Answered 2021-Nov-27 at 16:16

            In my case I was using RNGCryptoServiceProvider in .NET 5 but when I updated to .NET 6 I got the same warning. After reading about it in this issue I changed my code from this:

            Source https://stackoverflow.com/questions/70109573

            QUESTION

            Crypto-js encryption and Python decryption using HKDF key
            Asked 2022-Mar-28 at 11:29

            Based on the example provided here on how to establish a shared secret and derived key between JS (Crypto-JS) and Python, I can end up with the same shared secret and derived key on both ends.

            However, when I try to encrypt as below, I cannot find a way to properly decrypt from Python. My understanding is that probably I am messing with the padding or salts and hashes.

            ...

            ANSWER

            Answered 2022-Mar-28 at 11:29

            The issue is that the key is not passed correctly in the CryptoJS code.

            The posted Python code generates LefjQ2pEXmiy/nNZvEJ43i8hJuaAnzbA1Cbn1hOuAgA= as Base64-encoded key. This must be imported in the CryptoJS code using the Base64 encoder:

            Source https://stackoverflow.com/questions/71632056

            QUESTION

            Exception "System.Security.Cryptography.CryptographicException" after Publishing project
            Asked 2022-Mar-19 at 05:01

            Everytime I publish my Blazor Server-project to my website domain, and opening the website, this exception occurs, and there's little to no help Googling it:

            And it says AppState.cs: line 21, so here's the codeline for it:

            This exception is not happening under debugging localhost. When I delete localStorage from the browser on my website, and refreshing, then everything works. But I don't want my customers having this exception and having to tell them to delete the localstorage everytime I'm publishing.

            My Program.cs if necessary:

            ...

            ANSWER

            Answered 2022-Mar-16 at 13:16

            Try to set Load User Profile to true in your IIS app pool in the advanced settings. see this answer, I hope that will help you!

            Source https://stackoverflow.com/questions/71494715

            QUESTION

            Chaum blind signature with blinding in JavaScript and verifying in Java
            Asked 2022-Mar-04 at 16:01

            I'm experimenting with Chaum's blind signature, and what I'm trying to do is have the blinding and un-blinding done in JavaScript, and signing and verifying in Java (with bouncy castle). For the Java side, my source is this, and for JavaScript, I found blind-signatures. I've created two small codes to play with, for the Java side:

            ...

            ANSWER

            Answered 2021-Dec-13 at 14:56

            The blind-signature library used in the NodeJS code for blind signing implements the process described here:

            No padding takes place in this process.

            In the Java code, the implementation of signing the blind message in signConcealedMessage() is functionally identical to BlindSignature.sign().
            In contrast, the verification in the Java code is incompatible with the above process because the Java code uses PSS as padding during verification.
            A compatible Java code would be for instance:

            Source https://stackoverflow.com/questions/70324926

            QUESTION

            KJUR jws jsrsasign: Cannot validate ES256 token on JWT.io
            Asked 2022-Mar-03 at 06:41

            We are trying to make a JWT token for Apple Search Ads using the KJUR jws library. We are using the API documents from Apple:

            https://developer.apple.com/documentation/apple_search_ads/implementing_oauth_for_the_apple_search_ads_api

            We are generating a private key (prime256v1 curve):

            openssl ecparam -genkey -name prime256v1 -noout -out private-key.pem

            Next we are generating a public key from the private key:

            openssl ec -in private-key.pem -pubout -out public-key.pem

            Next we setup the header and payload:

            ...

            ANSWER

            Answered 2022-Mar-02 at 07:47

            The issue is caused by an incorrect import of the key.

            The posted key is a PEM encoded private key in SEC1 format. In getKey() the key is passed in JWK format, specifying the raw private key d. The PEM encoded SEC1 key is used as the value for d. This is incorrect because the raw private key is not identical to the SEC1 key, but is merely contained within it.

            To fix the problem, the key must be imported correctly. jsrsasign also supports the import of a PEM encoded key in SEC1 format, but then it also needs the EC parameters, s. e.g. here. For prime256v1 aka secp256r1 this is:

            Source https://stackoverflow.com/questions/71307444

            QUESTION

            Is it possible to get ISO9796-2 signature with Trailer = 'BC' in Javacard?
            Asked 2022-Feb-24 at 10:46

            I trying to get the RSA signature as described in Annex A2.1 of EMV book 2. As I understand it was described in ISO9796-2 as scheme 1, option 1. So, the resulting signature should contain a Header equal to '6A' and a Trailer equal to 'BC'.

            The algorithms ALG_RSA_SHA_ISO9796 and ALG_RSA_SHA_ISO9796_MR are the only suitable that I could find. But they acting like scheme 1, option 2 with a Trailer equal to '33cc'

            Is it possible to get a signature with Trailer = 'BC'?

            Javacard example code:

            ...

            ANSWER

            Answered 2022-Feb-24 at 10:46

            You can generate such signature using Cipher.ALG_RSA_NOPAD in decrypt mode.

            Pseudocode:

            Source https://stackoverflow.com/questions/71243483

            QUESTION

            How to transfer custom SPL token by '@solana/web3.js' and '@solana/sol-wallet-adapter'
            Asked 2022-Jan-29 at 21:02

            Hello I am trying to transfer a custom SPL token with the solana-wallet adapter. However i am having trouble getting the wallet's secret key/signing the transaction.

            I've looked at these answers for writing the transfer code but i need to get the Singer and i have trouble figuring out how with solana-wallet adapter. These examples hardcode the secret key and since i'm using a wallet extension this is not possible.

            How can you transfer SOL using the web3.js sdk for Solana?

            How to transfer custom token by '@solana/web3.js'

            according to this issue on the webadapter repo https://github.com/solana-labs/wallet-adapter/issues/120 you need to:

            1. Create a @solana/web3.js Transaction object and add instructions to it
            2. Sign the transaction with the wallet
            3. Send the transaction over a Connection

            But i am having difficulty finding examples or documentation as to how to do step 1 and 2.

            ...

            ANSWER

            Answered 2021-Dec-06 at 13:51

            So i found a way to do this, it requires some cleanup and error handling but allows for a custom token transaction via @solana/wallet-adapter.

            Source https://stackoverflow.com/questions/70224185

            QUESTION

            From base64-encoded public key in DER format to COSE key, in Python
            Asked 2022-Jan-01 at 10:34

            I have a base64-encoded public key in DER format. In Python, how can I convert it into a COSE key?

            Here is my failed attempt:

            ...

            ANSWER

            Answered 2022-Jan-01 at 07:49

            The posted key is an EC key for curve P-256 in X.509 format.

            With an ASN.1 parser (e.g. https://lapo.it/asn1js/) the x and y coordinates can be determined:

            Source https://stackoverflow.com/questions/70542577

            QUESTION

            Why are signatures created with ecdsa Python library not valid with coincurve?
            Asked 2021-Dec-25 at 14:41

            I'm switching from the pure Python ecdsa library to the much faster coincurve library for signing data. I would also like to switch to coincurve for verifying the signatures (including the old signatures created by the ecdsa library).

            It appears that signatures created with ecdsa are not (always?) valid in coincurve. Could someone please explain why this is not working? Also, it seems that cryptography library is able to validate both ecdsa signatures and coincurve signatures without issues, consistently.

            What is even more confusing, if you run below script a few times, is that sometimes it prints point 3 and other times it does not. Why would coincurve only occasionally find the signature valid?

            ...

            ANSWER

            Answered 2021-Dec-25 at 14:41

            Bitcoin and the coincurve library use canonical signatures while this is not true for the ecdsa library.

            What does canonical signature mean?
            In general, if (r,s) is a valid signature, then (r,s') := (r,-s mod n) is also a valid signature (n is the order of the base point).
            A canonical signature uses the value s' = -s mod n = n - s instead of s, i.e. the signature (r, n-s), if s > n/2, s. e.g. here.

            All signatures from the ecdsa library that were not been successfully validated by the coincurve library in your test program have an s > n/2 and thus are not canonical, whereas those that were successfully validated are canonical.

            So the fix is simply to canonize the signature of the ecdsa library, e.g.:

            Source https://stackoverflow.com/questions/70477905

            Community Discussions, Code Snippets contain sources that include Stack Exchange Network

            Vulnerabilities

            No vulnerabilities reported

            Install Ciphey

            If you're having trouble with installing Ciphey, read this.

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            For any new features, suggestions and bugs create an issue on GitHub. If you have any questions check and ask questions on community page Stack Overflow .
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            pip install ciphey

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            gh repo clone Ciphey/Ciphey

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            git@github.com:Ciphey/Ciphey.git

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